坚固体孕震模式的地磁日变化感应电流异常证据与完善——以2016年杂多6.2级、 2017年九寨沟7.0级和2017年米林6.9级地震为例

doi:10.3969/j.issn.0253-4967.2022.06.013

地震地质 ›› 2022, Vol. 44 ›› Issue (6): 1574-1596.DOI: 10.3969/j.issn.0253-4967.2022.06.013

坚固体孕震模式的地磁日变化感应电流异常证据与完善——以2016年杂多6.2级、 2017年九寨沟7.0级和2017年米林6.9级地震为例

戴勇¹⁾(), 吴迎燕²⁾, 冯志生³⁾^,^*(), 姚丽⁴⁾, 姜楚峰⁵⁾, 孙君嵩³⁾, 章鑫⁶⁾, 冯丽丽⁷⁾, 李军辉⁸⁾

1)内蒙古自治区地震局, 呼和浩特 010010
2)中国地震局地震预测研究所, 北京 100003
3)江苏省地震局, 南京 210014
4)中国地震台网中心, 北京 100045
5)湖北省地震局, 武汉 430071
6)广东省地震局, 广州 510070
7)青海省地震局, 西宁 810001
8)安徽省地震局, 合肥 230031

收稿日期:2021-12-26 修回日期:2022-05-20 出版日期:2022-12-20 发布日期:2023-01-21
通讯作者: 冯志生
作者简介:戴勇, 男, 1981年生, 2009年于中国地震局兰州地震研究所获固体地球物理学硕士学位, 高级工程师, 主要研究方向为数据处理及地震预测研究, E-mail: daiyong06@mails.ucas.ac.cn。
基金资助:
中国地震局地震科技星火计划项目(XH200501);中国地震局地震预测研究所基本科研业务专项(2021IEF0709);国家重点研发计划项目(2017YFC1500502);中国地震局监测预报司震情跟踪项目

EVIDENCE AND REFINEMENT OF GEOMAGNETIC DIURNAL INDUCED CURRENT ANOMALY BASED ON HARD BODY SEIS-MOGENIC MODEL: TAKING THE 2016 ZADOI M6.2 EARTH-QUAKE, THE 2017 JIUZHAIGOU M7.0 EARTHQUAKE, AND THE 2017 MILIN M6.9 EARTHQUAKE AS EXAMPLES

DAI Yong¹⁾(), WU Ying-yan²⁾, FENG Zhi-sheng³⁾^,^*(), YAO Li⁴⁾, JIANG Chu-feng⁵⁾, SUN Jun-song³⁾, ZHANG Xin⁶⁾, FENG Li-li⁷⁾, LI Jun-hui⁸⁾

1)Earthquake Agency of Inner Mongolia Autonomous Region, Hohhot 010010, China
2)Institute of Earthquake Forecasting, China Earthquake Administration, Beijing 100003, China
3)Jiangsu Earthquake Agency, Nanjing 210014, China
4)China Earthquake Networks Center, Beijing 100045, China
5)Hubei Earthquake Agency, Wuhan 430071, China
6)Guangdong Earthquake Agency, Guangzhou 510070, China
7)Qinghai Earthquake Agency, Xining 810001, China
8)Anhui Earthquake Agency, Hefei 230031, China

Received:2021-12-26 Revised:2022-05-20 Online:2022-12-20 Published:2023-01-21
Contact: FENG Zhi-sheng

摘要/Abstract

摘要：

文中研究了2016年杂多6.2级、 2017年九寨沟7.0级和2017年米林6.9级地震前1~3a内地磁日变化感应电流的线状集中分布和短期原地重现异常的空间分布特征, 发现线状感应电流的重叠段有围空现象, 并依据重叠段异常产生的机理丰富和完善了坚固体孕震模式, 获得的主要结论包括: 1)重叠段空区是坚固体在中-下地壳和上地幔分布范围的反映, 这与地震空区是坚固体在中-上地壳分布范围的反映相类似, 重叠段空区是发生在震前1~3a、坚固体孕震模式第3阶段的异常; 2)重叠段异常是中-下地壳和上地幔高阻体之间出现带有上拱性质的相互拆离滑动事件导致的高阻体之间高导层出现的短时间高导电流通道, 其中上述拆离滑动事件是由深部热流体上涌引起的, 它是坚固体孕震模式中发生在中-下地壳和上地幔的能量向坚固体运移的事件; 3)临震阶段震源体孕震断层内的各个密封高压流体不会同时破裂, 早期破裂的密封高压流体与深部上涌进入断层内的高压热流体及断层内原有的自由水可能使得断层内遍布自由水, 并在震源体孕震断层内形成有临震意义的高导电流通道, 发现临震阶段震源体孕震断层内的高导电流通道对地震短临预报具有现实意义; 4)重叠段异常探测发现的中-下地壳和上地幔拆离滑动事件可能是大陆下方有热流体上涌运移参与的慢地震, 但这一推测还需要基于测震学原理的研究结果加以论证。

关键词: 地磁日变化, 感应电流, 热流体, 上涌, 拆离滑动, 孕震模式, 坚固体, 慢地震

Abstract:

This paper studies the linear concentrated distribution of geomagnetic diurnal induced current and the spatial distribution characteristics of short-term in-situ recurrence anomalies in the 1~3 years before the 2016 Zadoi M6.2 earthquake, the 2017 Jiuzhaigou M7.0 earthquake and the 2017 Milin M6.9 earthquake. The main conclusions are as follows:
(1)The overlapping segment anomalies occurring within 1~3 years before strong earthquakes usually have the phenomenon of seismic gaps. The overlapping segment gap is a large high-resistance body and also a hard body(hard inclusion)in the seismogenic model of hard body. Overlapping segment gap and seismic gap are the detection results of hard body with different depth distribution range by different physical detection methods. The distribution range of hard body is delineated by seismic gap in the upper and middle crust and overlapping segment gap in the middle-lower crust and upper mantle. The overlapping segment gaps occurred within 1~3 years before strong earthquakes, which are the anomalies in the third stage of the seismogenic model. The seismic gap before strong earthquakes has different stages. For example, background gaps are formed decades of years before strong earthquakes, and the gaps formed again about 1 year before the earthquakes.
(2)The overlapping segment anomalies occurring within 1~3 years before strong earthquakes reflect the formation of short-time high conductive current channels in the high conductive layers among high resistance bodies. These short-time high conductive current channels are caused by the mutually detached slip events with up-arching property among the high-resistivity bodies located in the middle-lower crust and upper mantle, resulting from the upwelling of deep thermal fluid. They are the events in which the energy in the middle-lower crust and upper mantle migrates to the hard body in the seismogenic model of hard body, while the seismic gap events are the ones in which the energy in the middle-upper crust migrates to the hard body before the earthquake.
(3)Based on the results of seismic high-pressure fluid experiments in recent years, and combined with the mechanism of overlapping segment seismic anomalies, it is considered that each sealed high-pressure fluid in the seismogenic fault of the source body will not rupture at the same time in the impending earthquake stage. The original free water in the fault, the sealed high-pressure fluid broken in the earlier stages, and the high-pressure thermal fluid upwelling into the fault in the deep may make the seismogenic fault of the source body full of free water, and may form a high-conductivity current channel in the fault with impending earthquake significance. The high-conductivity current channel may be a real impending earthquake anomaly. Obviously, it is found that the high-conductivity current channel in the fault in the impending earthquake stage has practical significance for the short-term and impending earthquake prediction.
(4)The detachment slip events detected from the overlapping segment anomalies are located below the strong earthquake source, which is similar to the phenomenon that slow earthquake zone is located below the earthquake zone. Although the relationship between slow earthquakes and earthquake above them is unclear, some scholars believe that slip events produce stress accumulation on the surface of locked plates. A slip event may trigger a destructive earthquake, that is, a high-incidence period of intermittent tremors and slips can produce a peak period of seismicity. The above views on slow earthquakes are similar to the relationship between the linear overlapping segment anomalies of induced current associated with geomagnetic diurnal variation and earthquakes. The detachment slip events detected from the overlapping segment anomalies may be similar to the inter-plate slow earthquake or slow slip involving the upwelling and migration of thermal fluid under the continent, but this speculation needs to be demonstrated based on the research results of seismology.

Key words: geomagnetic diurnal variation, induced current, thermal fluid, upwelling, detached slip, seismogenic mode, hard body, slow earthquake

中图分类号:

P315.721

戴勇, 吴迎燕, 冯志生, 姚丽, 姜楚峰, 孙君嵩, 章鑫, 冯丽丽, 李军辉. 坚固体孕震模式的地磁日变化感应电流异常证据与完善——以2016年杂多6.2级、 2017年九寨沟7.0级和2017年米林6.9级地震为例[J]. 地震地质, 2022, 44(6): 1574-1596.

DAI Yong, WU Ying-yan, FENG Zhi-sheng, YAO Li, JIANG Chu-feng, SUN Jun-song, ZHANG Xin, FENG Li-li, LI Jun-hui. EVIDENCE AND REFINEMENT OF GEOMAGNETIC DIURNAL INDUCED CURRENT ANOMALY BASED ON HARD BODY SEIS-MOGENIC MODEL: TAKING THE 2016 ZADOI M6.2 EARTH-QUAKE, THE 2017 JIUZHAIGOU M7.0 EARTHQUAKE, AND THE 2017 MILIN M6.9 EARTHQUAKE AS EXAMPLES[J]. SEISMOLOGY AND GEOLOGY, 2022, 44(6): 1574-1596.

图/表 8

表1 地磁日变化感应电流的线状集中分布与短期原地重现异常参数

Table1 Linear concentration distribution and short-term in-situ recurrence anomalies of induced current of geomagnetic diurnal variation

序号	日期	日期间隔/d	备注	序号	日期	日期间隔/d	备注
1	2015-10-09 2015-10-14	5	冯志生等(2020)发表论文的图 2 中将这3d异常叠加在一起, 由于重叠长度不同, 本文将其分开	10	2016-09-11 2016-09-25	14
2	2015-10-10 2015-10-14	4		11	2016-09-11 2016-09-29	18
3	2016-04-19 2016-04-29	10		12	2016-09-25 2016-09-28	3
4	2016-05-13 2016-05-14	1		13	2016-09-25 2016-09-29	4
5	2016-05-30 2016-06-08	9		14	2016-09-25 2016-10-01	6
7	2016-06-08 2016-06-14	6	2条重叠段异常	15	2016-10-26 2016-10-29	4	2条重叠段异常
8	2016-08-30 2016-09-03	4		16	2016-10-26 2016-10-31	5	4条重叠段异常
9	2016-08-30 2016-09-11	12

图 1 地磁日变化感应电流的线状集中分布与短期原地重现异常

Fig. 1 Linear concentration distribution of induced current of geomagnetic diurnal variation

图 2 重叠段异常与中-下地壳高导层顶界面埋深及地震空间分布图(据彭聪等, 2018修改)

Fig. 2 Overlapping segment anomalies, burial depth of the top boundary of high conductivity layer in middle-lower crust and seismic spatial distribution(Adapted after PENG Cong et al., 2018).

图 3 重叠段异常与上地幔高导层顶界面埋深及地震空间分布图(据彭聪等, 2018修改)

Fig. 3 Overlapping segment anomalies, the top boundary burial depth of upper mantle high conductivity layer and seismic spatial distribution(Adapted after PENG Cong et al., 2018).

图 4 重叠段、重叠段空区及地震分布图

Fig. 4 Overlapping segments, gaps of overlapping segments and seismic distribution.

图 5 重叠段端部、重叠段端部空区及地震分布图

Fig. 5 Ends of overlapping segments, gaps at the ends of overlapping segments and seismic distribution.

图 6 重叠段空区、震前小地震空区及地震分布

Fig. 6 Overlapping segment gaps and small earthquake gaps before strong earthquake and earthquake distribution.

图 7 重叠段端部空区、震前小地震空区及地震分布

Fig. 7 Gaps at the ends of overlapping segments, small earthquake gaps before strong earthquakes and earthquake distribution.

参考文献 59

[1]	艾萨·伊斯马伊力, 陈界宏, 毛志强. 2020. 利用帕金森矢量检测2019年长宁6.0级地震的地磁场变化[J]. 地震, 40(2): 91-99.
	AISA Yisimayili, CHEN Jie-hong, MAO Zhi-qiang. 2020. Using Parkinson vector analysis to detect the geomagnetic changes in the Sichuan Changning M6.0 earthquakes of June 17, 2019[J]. Earthquake, 40(2): 91-99. (in Chinese)
[2]	白玲, 李国辉, 宋博文. 2017. 2017年西藏米林6.9级地震震源参数及其构造意义[J]. 地球物理学报, 60(12): 4956-4963.
	BAI Ling, LI Guo-hui, SONG Bo-wen. 2017. The source parameters of the M6.9 Mainling, Tibet earthquake and its tectonic implications[J]. Chinese Journal of Geophysics, 60(12): 4956-4963. (in Chinese)
[3]	白武明, 马麦宁, 柳江琳. 2000. 地壳岩石波速和电导率实验研究[J]. 岩石力学与工程学报, 19(S1): 899-904.
	BAI Wu-ming, MA Mai-ning, LIU Jiang-lin. 2000. Testing study on elastic wave velocities and electrical conductivity of crustal rocks[J]. Chinese Journal of Rock Mechanics and Engineering, 19(S1): 899-904. (in Chinese)
[4]	陈进宇, 杨晓松. 2017. 地壳岩石矿物电导率实验研究进展[J]. 地球物理学进展, 32(6): 2281-2294.
	CHEN Jin-yu, YANG Xiao-song. 2017. Review of experimental studies on electrical conductivity of crustal rocks and minerals[J]. Progress in Geophysics, 32(6): 2281-2294. (in Chinese)
[5]	邓起东, 冉勇康, 杨晓平, 等. 2007. 中国活动构造图(1:400万)[CM]. 北京: 地震出版社.
	DENG Qi-dong, RAN Yong-kang, YANG Xiao-ping, et al. 2007. Active Tectonic Map of China(1:4 000 000)[CM]. Seismological Press, Beijing. (in Chinese)
[6]	杜建国, 仵柯田, 孙凤霞. 2018. 地震成因综述[J]. 地学前缘, 25(4): 255-267. DOI
	DU Jian-guo, WU Ke-tian, SUN Feng-xia. 2018. Earthquake generation: A review[J]. Earth Science Frontiers, 25(4): 255-267. (in Chinese) DOI
[7]	范国华, 姚同起, 顾左文, 等. 1994. 琼州海峡地区地磁变化特征及其分析[J]. 地震学报, 16(2): 220-226.
	FAN Guo-hua, YAO Tong-qi, GU Zuo-wen, et al. 1994. Characteristics and analysis of geomagnetic variation in Qiongzhou Strait[J]. Acta Seismologica Sinica, 16(2): 220-226. (in Chinese)
[8]	冯志生, 姜楚峰, 冯丽丽, 等. 2020. 短期重现性地磁日变化感应电流集中分布与地震关系初步研究[J]. 中国地震, 36(3): 502-516.
	FENG Zhi-sheng, JIANG Chu-feng, FENG Li-li, et al. 2020. A preliminary study on relationship between induced current of geomagnetic diurnal variation with short-term reproducibility concentration distribution and earthquakes[J]. Earthquake Research in China, 36(3): 502-516. (in Chinese)
[9]	高春杨, 黄晓葛, 代唯琪, 等. 2020. 高温高压下上地幔岩石电导率实验研究[J]. 地球物理学报, 63(9): 3409-3419.
	GAO Chun-yang, HUANG Xiao-ge, DAI Wei-qi, et al. 2020. Experimental study on electrical conductivity of pyrolite at high temperature and high pressure[J]. Chinese Journal of Geophysics, 63(9): 3409-3419. (in Chinese)
[10]	高翔. 2017. 俯冲带板间地震活动的热-力学特征[J]. 海洋与湖沼, 48(6): 1235-1243.
	GAO Xiang. 2017. Thermo-mechanics of interplate seismicity at subduction zones[J]. Oceanologia et Limnologia Sinica, 48(6): 1235-1243. (in Chinese)
[11]	龚绍京, 刘双庆, 梁明剑. 2017. 中国大陆地磁帕金森矢量特征及其与主要构造关系[J]. 地震学报, 39(1): 47-63.
	GONG Shao-jing, LIU Shuang-qing, LIANG Ming-jian. 2017. Characteristics of geomagnetic Parkinson vector in Chinese mainland and their tectonic implication[J]. Acta Seismologica Sinica, 39(1): 47-63. (in Chinese)
[12]	韩亮, 周永胜, 姚文明. 2012. 中地壳断层带内微裂隙愈合与高压流体形成条件的模拟实验研究[J]. 国际地震动态, (6): 234.
	HAN Liang, ZHOU Yong-sheng, YAO Wen-ming. 2012. A simulating experimental study on crack healing and the formation of high pore fluid pressure in faults of middle crust[J]. Recent Developments in World Seismology, (6): 234. (in Chinese)
[13]	韩亮, 周永胜, 姚文明. 2013. 中地壳断层带内微裂隙愈合与高压流体形成条件的模拟实验研究[J]. 地球物理学报, 56(1): 91-105.
	HAN Liang, ZHOU Yong-sheng, YAO Wen-ming. 2013. A simulating experimental study on crack healing and the formation of high pore fluid pressure in faults of middle crust[J]. Chinese Journal of Geophysics, 56(1): 91-105. (in Chinese) DOI URL
[14]	侯作中, 史铁生. 1984. 云南省的地磁短周期变化异常[J]. 地震学报, 6(3): 287-293.
	HOU Zuo-zhong, SHI Tie-sheng. 1984. Short-period geomagnetic variation anomaly in Yunnan Province[J]. Acta Seismologica Sinica, 6(3): 287-293. (in Chinese)
[15]	姜楚峰, 吴迎燕, 冯志生, 等. 2022. 短期线状集中分布地磁日变化感应电流异常机理初步解释: 以2012年唐山4.8级地震为例[J]. 中国地震, 38(2): 226-238.
	JIANG Chu-feng, WU Ying-yan, FENG Zhi-sheng, et al. 2022. Mechanism of induced current anomaly of geomagnetic diurnal variation with short-term in-situ recurrence and linear centralized distribution: A case of 2012 Tangshan M_S4.8 earthquake[J]. Earthquake Research in China, 38(2): 226-238. (in Chinese)
[16]	金胜, 魏文博, 汪硕, 等. 2010. 青藏高原地壳高导层的成因及动力学意义探讨: 大地电磁探测提供的证据[J]. 地球物理学报, 53(10): 2376-2385.
	JIN Sheng, WEI Wen-bo, WANG Shuo, et al. 2010. Discussion of the formation and dynamic signification of the high conductive layer in Tibetan crust[J]. Chinese Journal of Geophysics, 53(10): 2376-2385. (in Chinese)
[17]	李军辉, 姜楚峰, 吴迎燕, 等. 2021. 强震前地磁日变化感应电流线状集中分布孕震机理研究[J]. 地震, 41(3): 219-228.
	LI Jun-hui, JIANG Chu-feng, WU Ying-yan, et al. 2021. Study on the linear concentrated distribution mechanism of induced current in geomagnetic diurnal variation before strong earthquakes[J]. Earthquake, 41(3): 219-228. (in Chinese)
[18]	梁姗姗, 雷建设, 徐志国, 等. 2018. 2017年四川九寨沟 M_S7.0 强震的余震重定位及主震震源机制反演[J]. 地球物理学报, 61(5): 2163-2175.
	LIANG Shan-shan, LEI Jian-she, XU Zhi-guo, et al. 2018. Relocation of aftershocks of the 2017 Jiuzhaigou, Sichuan, M_S7.0 earthquake and inversion for focal mechanism of the mainshock[J]. Chinese Journal of Geophysics, 61(5): 2163-2175. (in Chinese)
[19]	梅世蓉. 1995a. 地震前兆场物理模式与前兆时空分布机制研究(一): 坚固体孕震模式的由来与证据[J]. 地震学报, 17(3): 273-282.
	MEI Shi-rong. 1995a. Study on physical model of earthquake precursor field and temporal and spatial distribution mechanism of earthquake precursors(I): Origin and evidence of solid seismogenic model[J]. Acta Seismologica Sinica, 17(3): 273-282. (in Chinese)
[20]	梅世蓉. 1995b. 地震前兆场物理模式及前兆分布特征与机制研究进展[J]. 地震, 15(S1): 2-22.
	MEI Shi-rong. 1995b. Development of research on the physical model of earthquake precursor field and the mechanism of precursors’ time-space distribution[J]. Earthquake, 15(S1): 2-22. (in Chinese)
[21]	梅世蓉, 宋治平, 薛艳. 1996. 中国巨大地震前地震活动环形分布图象与规律[J]. 地震学报, 18(4): 413-419.
	MEI Shi-rong, SONG Zhi-ping, XUE Yan. 1996. Annular distribution pattern and regularity of seismic activity before China giant earthquake[J]. Acta Seismologica Sinica, 18(4): 413-419. (in Chinese)
[22]	梅世蓉. 1996a. 地震前兆场物理模式与前兆时空分布机制研究(二): 强震孕育时应力、应变场的演化与地震活动、地震前兆的关系[J]. 地震学报, 18(1): 1-10.
	MEI Shi-rong. 1996a. Study on physical model of earthquake precursor field and temporal and spatial distribution mechanism of earthquake precursors(Ⅱ): Relationship between evolution of stress and strain field and seismicity and earthquake precursors during strong earthquake preparation[J]. Acta Seismologica Sinica, 18(1): 1-10. (in Chinese) DOI URL
[23]	梅世蓉. 1996b. 地震前兆场物理模式与前兆时空分布机制研究(三): 强震孕育时地震活动与地壳形变场异常及机制[J]. 地震学报, 18(2): 170-178.
	MEI Shi-rong. 1996b. Study on physical model of earthquake precursor field and temporal and spatial distribution mechanism of earthquake precursors(Ⅲ): Anomaly and mechanism of seismic activity and crustal deformation field during strong earthquake preparation[J]. Acta Seismologica Sinica, 18(2): 170-178. (in Chinese)
[24]	梅世蓉. 1999. 邢台地震孕育发生模型及其前兆机理探讨[J]. 地震, 19(1): 1-10.
	MEI Shi-rong. 1999. Model of preparation and generation of Xingtai earthquake and mechanism of its precursors[J]. Earthquake, 19(1): 1-10. (in Chinese)
[25]	牛树银, 侯泉林, 王宝德, 等. 2003. 华北地区拆离滑脱带控震作用初探[J]. 地震研究, 26(3): 257-264.
	NIU Shu-yin, HOU Quan-lin, WANG Bao-de, et al. 2003. Primary exploration of earthquake-controlling of detachment zone in North China[J]. Journal of Seismological Research, 26(3): 257-264. (in Chinese)
[26]	彭聪, 卢占武, 韩江涛, 等. 2018. 中国大陆深层区域构造格架: 重、磁、电、震地球物理图集成[M]. 北京: 地质出版社.
	PENG Cong, LU Zhan-wu, HAN Jiang-tao, et al. 2018. Gravity, Magnetic, Electrical and Seismic Geophysical Atlas of Deep Tectonic Framework in China’s Mainland[M]. Seismological Press, Beijing. (in Chinese)
[27]	宋治平, 梅世蓉, 尹祥础. 1999. 强大地震前地震活动增强区及其力学研究[J]. 地震学报, 21(3): 271-277.
	SONG Zhi-ping, MEI Shi-rong, YIN Xiang-chu. 1999. Study on seismicity enhancement area and its mechanics before strong earthquakes[J]. Acta Seismologica Sinica, 21(3): 271-277. (in Chinese)
[28]	孙翔宇, 詹艳, 赵凌强, 等. 2020. 东昆仑断裂带东端和2017年九寨沟7.0级地震区深部电性结构探测[J]. 地震地质, 42(1): 182-197.
	SUN Xiang-yu, ZHAN Yan, ZHAO Ling-qiang, et al. 2020. Electrical structure of the 2017 M_S7.0 earthquake region and the eastern terminus of the east Kunlun Fault[J]. Seismology and Geology, 42(1): 182-197. (in Chinese)
[29]	王桥, 黄清华. 2016. 华北地磁感应矢量时空特征分析[J]. 地球物理学报, 59(1): 215-228.
	WANG Qiao, HUANG Qing-hua. 2016. The spatio-temporal characteristics of geomagnetic induction vectors in North China[J]. Chinese Journal of Geophysics, 59(1): 215-228. (in Chinese)
[30]	翁爱华, 李世文, 李建平, 等. 2017. 深部电磁感应研究进展[J]. 地球物理学进展, 32(4): 1679-1692.
	WENG Ai-hua, LI Shi-wen, LI Jian-ping, et al. 2017. Progress in deep electromagnetic induction studies[J]. Progress in Geophysics, 32(4): 1679-1692. (in Chinese)
[31]	徐文耀. 2009. 地球电磁现象物理学[M]. 合肥: 中国科学技术大学出版社.
	XU Wen-yao. 2009. Physics of the Earth’s Electromagnetic Phenomena[M]. University of Science and Technology of China Press, Hefei. (in Chinese)
[32]	徐文耀, 祁骙, 王仕明. 1978. 甘肃省东部地区短周期地磁变化异常及其与地震的关系[J]. 地球物理学报, 21(3): 218-224.
	XU Wen-yao, QI Kui, WANG Shi-ming. 1978. On the short period geomagnetic variation anomaly of the eastern Kansu Province[J]. Chinese Journal of Geophysics, 21(3): 218-224. (in Chinese)
[33]	薛艳, 刘杰, 宋治平, 等. 2018. 汶川地震前地震活动特征的普遍性及其机理探讨[J]. 地球物理学报, 61(5): 1891-1906.
	XUE Yan, LIU Jie, SONG Zhi-ping, et al. 2018. On the universality and mechanism interpretation of the seismicity characteristics before the 2008 Wenchuan M_S8.0 earthquake[J]. Chinese Journal of Geophysics, 61(5): 1891-1906. (in Chinese)
[34]	薛艳, 周龙泉, 马宏生, 等. 2010. 利用小震重新定位结果研究河北文安地震前地震活动三维空间特征[J]. 地震, 30(1): 10-19.
	XUE Yan, ZHOU Long-quan, MA Hong-sheng, et al. 2010. Characteristics of seismic activity in 3-D space before Wen’an earthquake, Hebei Province by small earthquake relocation in the capital area of China[J]. Earthquake, 30(1): 10-19. (in Chinese)
[35]	杨杰, 李琪, 袁伊人. 2021. 2013年3月3日洱源 M_S5.5 地震前地磁转换函数异常研究[J]. 地震学报, 43(2): 215-226.
	YANG Jie, LI Qi, YUAN Yi-ren. 2021. Geomagnetic transform function anomaly before the M_S5.5 Eryuan earthquake on March 3, 2013[J]. Acta Seismologica Sinica, 43(2): 215-226. (in Chinese)
[36]	杨宜海, 范军, 花茜, 等. 2017. 近震全波形反演2017年九寨沟M7.0地震序列震源机制解[J]. 地球物理学报, 60(10): 4098-4104.
	YANG Yi-hai, FAN Jun, HUA Qian, et al. 2017. Inversion for the focal mechanisms of the 2017 Jiuzhaigou M7.0 earthquake sequence using near-field full waveforms[J]. Chinese Journal of Geophysics, 60(10): 4098-4104. (in Chinese)
[37]	尹海权. 2017. 慢地震幕式震颤与慢滑移: 特征、成因与新进展[J]. 中国地质, 44(6): 1259-1260.
	YIN Hai-quan. 2017. Slow seismic episodic trembling and slow gliding: Characteristics, genesis and new research progress[J]. Geology in China, 44(6): 1259-1260. (in Chinese)
[38]	张国民, 李丽. 2003. 地壳介质的流变性与孕震模型[J]. 地震地质, 25(1): 1-10.
	ZHANG Guo-min, LI Li. 2003. Rheology of crustal media and a related seismogenic model[J]. Seismology and Geology, 25(1): 1-10. (in Chinese)
[39]	张晶, 孙柏成. 2001. 张北 M_S6.2 地震前重力异常及异常机制探讨[J]. 地震, 21(2): 75-78.
	ZHANG Jing, SUN Bai-cheng. 2001. The gravity anomaly before the Zhangbei earthquake with M_S6.2 and analysis of its mechanism[J]. Earthquake, 21(2): 75-78. (in Chinese)
[40]	张晶, 孙柏成, 张成强. 1998. 唐山地震的重力异常及其震后变化[J]. 地震, 18(3): 293-298.
	ZHANG Jing, SUN Bai-cheng, ZHANG Cheng-qiang. 1998. Gravity anomaly before Tangshan earthquake and gravity changes after the earthquake[J]. Earthquake, 18(3): 293-298. (in Chinese)
[41]	章鑫, 冯志生, 袁桂平. 2019. 基于地磁垂直分量反相位现象的地下畸变电流正演计算[J]. 大地测量与地球动力学, 39(6): 596-601.
	ZHANG Xin, FENG Zhi-sheng, YUAN Gui-ping.2019. Calculating the distortion current based on anti-phase phenomena of the geomagnetic vertical component[J]. Journal of Geodesy and Geodynamics, 39(6): 596-601. (in Chinese)
[42]	章鑫, 姚丽, 冯志生. 2020. 青藏高原东南缘深部地壳流与地磁日变化短时畸变源电流的联系[J]. 地球物理学报, 63(10): 3804-3817.
	ZHANG Xin, YAO Li, FENG Zhi-sheng. 2020. Relationship between deep crustal flows and source currents of short time geomagnetic diurnal-variations distortion in southeast margin of Qinghai-Tibet Plateau[J]. Chinese Journal of Geophysics, 63(10): 3804-3817. (in Chinese)
[43]	张永仙, 石耀霖, 刘桂萍. 2000. 热物质上涌与震前重力异常关系初探[J]. 地震, 20(S1): 135-142.
	ZHANG Yong-xian, SHI Yao-lin, LIU Gui-ping. 2000. Preliminary study on the relationship between upwelling of hot material and gravity anomaly before earthquake[J]. Earthquake, 20(S1): 135-142. (in Chinese)
[44]	张媛媛, 周永胜. 2012. 断层脆塑性转化带的强度与变形机制及其流体和应变速率的影响[J]. 地震地质, 34(1): 172-194.
	ZHANG Yuan-yuan, ZHOU Yong-sheng. 2012. The strength and deformation mechanisms of brittle-plastic transition zone, and the effects of strain rate and fluids[J]. Seismology and Geology, 34(1): 172-194. (in Chinese)
[45]	赵旭东, 杨冬梅, 何宇飞, 等. 2014. Sq等效电流在太阳活动周中的分析研究[J]. 地球物理学报, 57(11): 3777-3788.
	ZHAO Xu-dong, YANG Dong-mei, HE Yu-fei, et al. 2014. The study of Sq equivalent current during the solar cycle[J]. Chinese Journal of Geophysics, 57(11): 3777-3788. (in Chinese)
[46]	中国地震局监测预报司. 2020. 地震电磁分析预测技术方法工作手册[M]. 北京: 地震出版社.
	Department of Monitoring and Forecasting, China Earthquake Administration. 2020. Working Manual of Seismic Electromagnetic Analysis and Prediction Techniques[M]. Seismological Press, Beijing. (in Chinese)
[47]	周永胜, 韩亮, 靖晨, 等. 2014. 龙门山断层脆-塑性转化带流变结构与汶川地震孕震机制[J]. 地震地质, 36(3): 882-895.
	ZHOU Yong-sheng, HAN Liang, JING Chen, et al. 2014. The rheological structures of brittle-plastic transition in Longmenshan fault zone and seismogenic mechanism of Wenchuan earthquake[J]. Seismology and Geology, 36(3): 882-895. (in Chinese)
[48]	周永胜, 何昌荣. 2009. 汶川地震区的流变结构与发震高角度逆断层滑动的力学条件[J]. 地球物理学报, 52(2): 474-484.
	ZHOU Yong-sheng, HE Chang-rong. 2009. The rheological structures of crust and mechanics of high-angle reverse fault slip for Wenchuan M_S8.0 earthquake[J]. Chinese Journal of Geophysics, 52(2): 474-484. (in Chinese)
[49]	朱涛, 詹艳, 孙翔宇, 等. 2020. 四川龙门山断裂带高精度地壳/岩石圈黏度结构及其动力学意义[J]. 地球物理学报, 63(1): 196-209.
	ZHU Tao, ZHAN Yan, SUN Xiang-yu, et al. 2020. High-resolution crustal/lithospheric viscosity of the Longmenshan fault zone, Sichuan Province and its geodynamic implications[J]. Chinese Journal of Geophysics, 63(1): 196-209. (in Chinese)
[50]	祝意青, 刘芳, 李铁明, 等. 2015. 川滇地区重力场动态变化及其强震危险含义[J]. 地球物理学报, 58(11): 4187-4196.
	ZHU Yi-qing, LIU Fang, LI Tie-ming, et al. 2015. Dynamic variation of the gravity field in the Sichuan-Yunnan region and its implication for seismic risk[J]. Chinese Journal of Geophysics, 58(11): 4187-4196. (in Chinese)
[51]	Chen C H, Hsu H L, Wen S, et al. 2013. Evaluation of seismo-electric anomalies using magnetic data in Taiwan[J]. Natural Hazards and Earth System Sciences, 13(3): 597-604.
[52]	Gao X, Wang K L. 2017. Rheological separation of the megathrust seismogenic zone and episodic tremor and slip[J]. Nature, 543(7645): 416-419. DOI URL
[53]	Küster M, Stöckhert B. 1999. High differential stress and sublithostatic pore fluid pressure in the ductile regime: Microstructural evidence for short-term post-seismic creep in the Sesia zone, western Alps[J]. Tectonophysics, 303(1-4): 263-277. DOI URL
[54]	Rikitake T. 1966. Electromagnetism and the Earth’s Interior[M]. Elsevier Publishing Company, Amsterdam.
[55]	Rikitake T. 1971. Electric conductivity anomaly in the earth’s crust and mantle[J]. Earth-Science Reviews, 7(1): 35-65. DOI URL
[56]	Rikitake T, Honkura Y. 1985. Solid Earth Geomagnetism[M]. Terra Scientific Publishing Company, Tokyo.
[57]	Rogers G, Dragert H. 2003. Episodic tremor and slip on the Cascadia subduction zone: The chatter of silent slip[J]. Science, 300(5627): 1942-1943. PMID
[58]	Untiedt J. 1970. Conductivity anomalies in central and southern Europe[J]. Journal of Geomagnetism and Geoelectricity, 22(1-2): 131-149. DOI URL
[59]	Wessel P, Smith W H F, Scharroo R, et al. 2013. Generic mapping tools: Improved version released[J]. Eos, Transactions American Geophysical Union, 94(45): 409-410.

坚固体孕震模式的地磁日变化感应电流异常证据与完善——以2016年杂多6.2级、 2017年九寨沟7.0级和2017年米林6.9级地震为例

EVIDENCE AND REFINEMENT OF GEOMAGNETIC DIURNAL INDUCED CURRENT ANOMALY BASED ON HARD BODY SEIS-MOGENIC MODEL: TAKING THE 2016 ZADOI M6.2 EARTH-QUAKE, THE 2017 JIUZHAIGOU M7.0 EARTHQUAKE, AND THE 2017 MILIN M6.9 EARTHQUAKE AS EXAMPLES

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